SBIR-STTR Award

A program is proposed that will extend (and build upon) the work already started by the Survivability Group of the Composites Affordability Initiative, Pervasive Team in developing methods for analyzing the effects of ballistic and hydrodynamic ram (HRAM) loading and damage in bonded/co-cured composite structures. Specifically, the objective will be to remedy a major shortcoming of current HRAM finite element codes, which are unable to accurately model the details that differentiate one joint design from another. The incorporation of stitching, z-pinning, co-curing, and bonding of the joints leads to different failure modes and paths. This is the area in which most work will be performed - in the proper selection of failure criteria within the joints as well as the entire model. Presently, the state-of-the-art is to use an elastic-plastic smeared properties technique in modeling the structure and "fuze elements" to model the joints. This program will greatly improve upon the current practices by developing cohesive elements, whose material properties can be determined by testing and incorporated into the HRAM finite element models.

Benefits:
Commercialization of the herein proposed research and development activity is in an area where AdTech has demonstrated successes in the past; however, the technology area is broader in scope. Thus we envision commercialization of a software module that can be added to existing, general purpose, fluid structure codes. These would include such codes as: (1) LS Dyna by LSTC, Inc., (2) MSC Dytran, (3) ALE 3-D, (4) CALE, (5) the Sandia CTH code couled to the old Dyna 3-D code for buildings, and (6) the Allegra Code. Further, the Cohesive Element 2-D code is being developed into a 3-D code, and our module would be adaptable to that code as well. Some of the key people associated with several of these codes have already been contacted and have expressed interest. User companies of these established codes are already comfortable with them, have historical data based upon them, can make comparative assessments, and thus are oftentimes reluctant to change --- even though there may be a known better software product available to them. At the same time, they may be quite receptive to adding an enhancement module to an existing code in order to expand its usefulness.

Keywords:
Finite Element Code Composites Hydrodynamic Failure Criteria Ballistic Survivability High Strain Rate

The aim of our Phase II activity is to incorporate the Cohesive Volumetric Plate and Shell (Finite) Elements into LS-DYNA3D, thus enhancing its capabilities in modeling HRAM loading and damage in composite structures. In Phase I, we reported on interlaminar failure criteria and modes, based on fracture mechanics. A damage-dependent bilinear cohesive element is used to capture the crack initiation, propagation, and arrest, while accounting for inertial effects. An algorithm was developed to compute essential toughness parameters (strain energy release rate G, stress intensity factor K) and the variations thereof, with crack length and adhesive effects. Experimental testing of double cantilever beam (DCB) specimens at various stroke rates, using an electronic circuit to measure crack-opening displacement, yielded data which enabled the calculation of material parameters used in the explicit CVFE/LS-DYNA formulation. As the next step, we propose to develop rate-dependent cohesive elements, and use this technique to analyze mixed-mode failure in stitched, z-pinned and other joint types. We shall investigate and incorporate contact-impact algorithms in LS-DYNA with filtering and damping. Experimental work will focus on hydrodynamic pulse tests, using the impact machine developed at the 46th test wing, thus simulating high-rate fracture dynamical scenarios. The material property data obtained in these tests will be incorporated into the LS-DYNA code with CVFE formulation, thus achieving the desired objectives of the SBIR.

Keywords:
LS-DYNA3D, COHESIVE VOLUMETRIC FINITE ELEMENT, DCB TESTING, Z-PINNED JOINTS, FRACTURE MECHANICS, HIGH STRAIN RATE, STITCHED